Fluid pressure brake



E. E. HEWITT FLUID PRESSURE BRAKE June 2l, 1938.

Filed Nov. 6. 1956 3 Sheets-Sheet 1 INVENTOR ELLIS E. HEWITT ATTORNEY mm 0S ON om. mm

June 2l, 1938. y E, E HEwlTT 2,121,543

FLUID PRESSURE BRAKE Filed Nov. 6. 1936 5 Sheets-Sheet 2.

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COA/Give InrerlocK Va|ve les 5C Pi pe BR INVENTOR ELLIS E. HEWITT www ATTORN EY June 2l, 1938. E. E. HEwlT-r FLUID PRESSURE BRAKE `s sheets-sheet s Filed Nov. 6, 1956 BcPspe INVENTOR ELLIS E. HEWITT ATTORNEY B. C, Pipe B4 E Patented `une 21, 1938 UNITED STATES ATENT oFFic FLUID PRESSURE BRAKE Application November e, 1936, serial N0. 109,483

21 claims.

This invention relates to fiuid pressure brakes, and more particularly to iiuid pressure brakes intended for high speed railway trains.

4 Safety is, of course, the guiding principle in the design of control equipment for railway trains. 'I'his is particularly true in the design of brake equipments for such trains,and becomes increasingly important when developing brake lequipments for the new light-weight, high speed, passenger trains. The new light-weight, high speed, passenger trains are designed to operate at speedsin excess of one hundred miles per hour, and since a train traveling at one hundred 'miles per hour passes over a distance of approximately one hundred and forty-seven feet per second, it will be appreciated that it is essential that the' brakes be applied with great rapidity, in' order that the train may be stopped in the shortest possible time and distance.

In 'the brake-equipments provided on the high speed passenger trains now in service, among other safety provisions is that for initiating and controlling applications of the brakes by mo-re than one mode of operation, sothat, in the event onecontrol means should fail, another may be resorted to. Furthermore, provision has alsobeen made in some of the brake equipments for automatically effecting an emergency application of the brakes in the event that a service application fails to materialize toa predetermined degrec within a chosen length of time, following movement of the brake valve handle to a selected service application position. By this provision, an application of the brakes is virtually assured, so that the train may be decelerated with a minimum of delay. This last mentioned provision is in the nature of an insuring means, and, of course, adds greatly to the safety of handling the train.

The many problems encountered in the braking of the new high speed trains has given rise tothe necessity of the employment of a large number of somewhat complicated devices. The addition of these vdevices to a brake equipment not only adds 'to its complication, but increases the cost of maintenance and, in some instances, also the liability of faulty operation. There is, therefore, a wide field for simplification and improvement in the various newly developed devices provided in the new brake equipments, so that not only will all of the functions essential to safety be retained, but also so that an increased degree of reliability, as well as a decreased rst cost and cost of maintenance, will result.

With the foregoing considerations in mind, it

is a principal object of the present invention to provide a brake equipment including a simplied and improved insuring means for insuring an application of the brakes in response to movement ofthe brake valve handle to a service application position.

A more specific object of the invention is to provideV animproved valve mechanism which operates as the essential element in the insuring means.

A yet further object of the invention is to provide a brake equipment of the character aforesaid, in which an insuring means is provided to eiiect an emergency application of the brakes upon failureof a service application to materialize to a predetermined degree within a chosen length of time, following movement of the brake valve handle to service application position.

A yet more specific object of the invention is to provide a brake equipment in which service applications of the brakes are normally initiated by straight air operation and emergency applications by automatic operation, and in which upon failure of a straight air application to materialize to a predetermined degree within a chosen length of time, following movement of the brake valve handle to a service application position, then there is automatically effected an application by automatic operation.

Yet further and more specific objects of the invention, dealing with specific constructions and arrangements of parts, for generally carrying out the aforestated objects, will be more fully appreciated from the following description of several embodiments of my invention, taken in connection with the attached drawings, wherein,

Fig. 1 shows in schematic and diagrammaticu form a. preferred embodiment of the invention as adapted to the head end or power car of a train.

Fig..2 is a view taken along the line 2 2 of the application insuring or interlock valve device shovvnV to the lower left of Fig. 1.

Fig. 3 shows in fragmentary form a modification of the brake equipment of Fig. 1, in which a different type of interlock or application insuring valve device is employed.

Fig. 4 shows also a modified form of the invention, in which the application insuring means involves the employment of a fluid pressure operated switch device.

Fig. 5 is still another modification employing yet another type of interlock or application insuring Valve device in a yet different arrangement with abrake pipe vent valve device.

EMBODIMENT or FIG. l

Referring now to Fig. 1, the principal parts of the brake equipment there illustrated comprise one or more brake cylinders I0, a relay valve device |I for controlling the supply of uid under pressure to and its release from the brake cylinders, an application and release magnet valve device I2 for controlling the operation of the relay valve device, a master switch device I3 for controlling the operation of the application and release magnet valve device, a service valve device I4, an emergency valve device I5, a. suppression selector valve device I6, a cut-off valve device I1, a brake pipe vent valve device |8, an interlock or application insuring valve device I9, a foot valve device 29, and a brake valve device 2|. The various reservoirs supplied include a main reservoir 23, which is connected to the usual compressor (not shown), an auxiliary reservoir 24, an emergency reservoir 25, and a timing reservoir |58.

The various control pipes include a main control pipe 28 (having connected thereto, by way of a double check valve device 21, two branches 29 and 39), a straight air pipe 3|, a brake pipe 32, a safetyl control pipe 33, and a. feed valve pipe 34.

Considering now more in detail the devices above enumerated, the relay valve device is embodied in a casing having disposed therein a piston 36 provided with a stem 31 carrying, pivotally mounted thereto at 38, a lever 39. The piston 36 is subject on one side to the pressure of fluid in a chamber 4D and on the other side t0 the pressure of uid in a chamber 4I.

When the piston 36 is actuated to the right, as by supply of uid under pressure to the chamber 40, the lever 39 functions to rst seat a release pilot valve 42, and then a main release valve 43, and after these two valves have been seated then functions to first unseat a supply pilot valve 44 and then a main supply valve 45. The release pilot valve 42 has a stem 46 provided with an intermediate reduced portion 41 disposed between the bifurcations forming the upper end of the lever 39. The release pilot valve 42 also has projecting to the right thereof a small stem 48, which stem projects through an aperture extending longitudinally of the main release valve 43 and has disposed on the end thereof nuts 49.

The main release valve 43 is slidable in a bore 5|] in the valve device casing, and is provided with a restricted port 5| in the slidable portion of the body, so as to establish a restricted communication between a chamber 52 and an exhaust port 53.

The main supply valve 45 is urged toward a seated position by a spring 55, While the supply pilot valve 44 is urged toward a seated position within the main supply valve by a smaller spring 56. The supply valve 45 co-ntrols communication between the feed valve pipe 34 and a chamber 58 within the valve device, which chamber is connected tothe brake cylinder Ill by way of brake cylinder pipe 59. The supply pilot valve 44 controls communication between a chamber 51, to the right of the main supply valve, and the aforementioned chamber 58. The chamber 51 is in communication with the feed valve pipe 34 by Way of a passage containing a restriction 60.

When the piston 36 moves to the right, it will be obvious that, since the lever 39 engages the plunger 6 I (which plunger is also in engagement with the spring-seated supply pilot valve 44) the lever 39 must actuate the release and supply valves in the sequence before stated.

Unseating of the pilot valve 44 releases fluid under pressure from the chamber 51 to the chamber 58, and thereby unloads the main supply valve 45 so that it may be readily unseated by the lever 39 with the applications of only a relatively light force.

When the main supply valve 45 is unseated, uid under pressure will flow from the feed valve pipe 34 to the chamber 58, and from thence by Way of pipe 59 to the two brake cylinders Ill. From the chamber 58, fluid under pressure will also flow by way of passage 63 to the chamber 4I, and when the pressure in this chamber is substantially equal to that in the chamber 40, the piston 36 will move to the left until the main supply valve 45 is seated by the spring 55, thus lapping the supply to the brake cylinders. It will be obvious, therefore, that the relay valve device will eifect a brake cylinder pressure corresponding to the degree of fluid pressure established in the chamber 40, and will function to maintain the brake cylinder pressures accordingly, as is well understood by those familiar with the art.

When fluid under pressure is released from the piston chamber 40, the lever 39 rotates in a counter-clockwise direction to unseat the release pilot valve 42, thereby permitting fluid under pressure to flow from chamber 58 to chamber 52 and thus unload the main release valve 43, which may be then readily unseated upon further movement of lever 39. Fluid under pressure in chamber 58 will ilow to the atmosphere via port 53, as will also that in chamber 52, in due time, via port 5I.

The application and release magnet valve device is embodied in a casing comprising a supply valve 66 and a release valve 61. The supply valve 66 is urged toward seated position by a spring 68, and toward unseated position by an electromagnet 69 when energized. The release valve 61 is urged toward unseated position by a spring 10, and toward seated position by another electromagnet 1| when energized.

When the supply valve 66 is seated and the release valve 61 is unseated, as is illustrated, the straight air pipe 3| is in communication With the atmosphere by Way of an exhaust port 12. When the release valve 61 is seated, and the supply valve 66 is unseated, fluid under pressure is supplied from the auxiliary reservoir to the straight air pipe 3|, by way of pipe 13, and past the unseated supply valve 66.

The masterr switch device I3 controls the operation of the application and release magnet valve device I2. This switch device is embodied in a casing having suitably disposed therein, and connected by a stem 14, two diaphragms 15 and 16. The two diaphragms coact with the enclosing casing to define two pressure tight chambers 11 and 18, as illustrated. 'I'he chamber 11 is in open communication with the control pipe 28, while the chamber 18 is in open communication with the straight air pipe 3| by way of a choke and check valve device 19, to be described presently.

Carried by and insulated from the diaphragm stem 14 is an electrical contact 8|. When moved to the left, this contact 8| is adapted to successively engage two stationary contacts 82 and 83, both of which are secured to and insulated from the casing of the switch device. The movable contact 8| is connected to one terminal of a battery 84, the other terminal of which is grounded as illustrated. The stationary contact r82 is connected to a release wire or conductor 85, which extends throughout the train and has connected thereto the release electromagnet II of v each of the application and release magnet valve devices I2 throughout the train. The stationary contact 33 is connected to an application wire 86, which also extends throughout the train and connects to the application electromagnet 69 in each of the application and release magnet valve devices. As will be observed from Fig. 1, the other terminal of each of the electromagnets is connected to ground. It should be obvious, therefore, that, as the switch contact 9| engages the contact 82, the release electromagnet 'II will be energized, and, upon engagement with the stationary contact 83, the application electromagnet 69 will be deenergized.

The service valve device I4 is embodied in a casing containing a piston 98 subject on one side to the pressure of uid in a chamber 89, and, on the other side, to the pressure of uid in a slide valve chamber 99. The piston 88 is provided with a stem 9|, which is recessed to receive and move coextensive therewith a slide valve 92. The stem 9| is also provided with shoulders or collars 93 for engaging, after a lost motion movement of the piston 83, a main slide valve 94.

The piston chamber 89 is connected to the brake pipe 32, while the slide valve chamber 99 is connected to the auxiliary reservoir 24. When the brake pipe 32 is charged, the piston 98 will be positioned as shown, in which position the auxiliary reservoir 24 is charged by way of a feed groove 95. At theI same time, the emergency reservoir is charged from the brake pipe by way of a spring loaded check valve 96, the communication to the emergency reservoir including pipe 9'I.

Upon a service or emergency rate of reduction of pressure in the brake pipe 32, the overbalancing pressure of iluid in the slide valve chamber 99 will move the piston 88 the full distance to the left, cutting oi communication between the brake pipe and both reservoirs 24 and 25. As the piston 88 moves to the left, the graduating valve 92 uncovers a port 99 in the main slide valve 94, and then shifts the main slide valve to a position where this port registers with a pipe and passage 99. Fluid under pressure may then flow from the auxiliary reservoir 24, and slide valve chamber 90, to the pipe 99. When the pressure in the slide Valve chamber 9i) drops slightly below the pressure in the chamber 89, the piston 88 will move to the right and cause the graduating Valve 92 to lap the service port 98.

Upon a restoration of the pressure in the brake pipe 32, and chamber 89, the piston'BB will move the full distance to the right, and shift the two slide valves 92 and 94 to the illustrated position, in which position cavity |99 in the main slide valve connects the pipe 99 to an exhaust port Il.

The emergency valve device I5 comprises a piston I 94 subject on one side to the pressure of viuid in a chamber |95, and on the other side to the pressure of fluid ina slide valve chamber |96 and a quick action chamber |91, the two latter chambers being connected by passage |03. 'Ihe piston |94 is provided with a stem |99, which is recessed to receive and move coextensive there-v in thestem |99 and projects into a recess in the main slide: valve. The holding pin ||2 is secured to a diaphragm I I3, which, on its uppermost side, is subject to fluid under pressure in a chamber II@ connected to emergency reservoir pipe 9'I by way of passage |92.

The piston chamber |95 is in open communication with the brake pipe 32. Upon a service rate of reduction in brake pipe pressure, `the overbalancing pressurein the slide valve chamber |96 gradually shifts the piston |99 to the right until suchtime as a small port H6 in the: graduating valve III) registers with a port lll in the main slide valve III, which, in the release position, is in communication with an exhaust port IIB. The size of the small port IIS is such that, when it registers with the main slide valve port I |'I, the pressure in the chamber |99, and consequently that in the quick action chamber |91, reduces at a rate such that the piston |94 is arrested in its movement to the right, and returned to the position illustrated when the pressure in chamber |95 slightly exceeds the diminished pressure in chamber |99. The purpose of this .arrangement is to prevent the piston |99 from moving the extreme distance to the right, and thus shifting the main slide valve when a service rate of reduction is eiected in brake pipe pressure.

When, however, brake pipe pressure is reduced at an emergency rate, the differential of pressure acting on the piston is greater, and it moves more promptly to its extreme right hand position. When the piston moves the extreme distance to the right, the main slide valve |I| assumes a position in which a passage ||9 is opened to the chamber |96. Fluid under pressure will then flow from the chamber |99, and quick action chamber lill, through the passage I9 to a piston chamber |29, where it will shift a piston |22 to the right to unseat a vent valve |23 against the bias of its spring |24. Unseating of the vent valve |23 will open communication between the brake pipe 32, adjacent the piston chamber |95, and the atmosphere, by way of passage |25, past the unseated valve and atmospheric passage |29. This will result in completely venting the brake pipe. Ultimately, however, the pressure in the slide valve chamber |96 and the quick action chamber I 'a' will be reduced to atmospheric pressure by virtue of the escape of fluid through a small port I2?. in the piston |22, whereupon the spring |29 will again seat the vent valve |23. Also, when the main slide valve II I is shifted to the right to application position, it connects pipe 9'I, leading to the emergency reservoir 25, with control pipe 39, so that fluid under pressure is supplied from the emergency reservoir to this pipe. This communication-is effected by cavity |3I in the main slide valve I I. At the same time, communication between pipes 91 and 99 is not established.

To insure that the main slide Valve |I I Will be shifted to application position in response to an emergency rate of reduction in brake pipe pressure, an additional port |32 is provided in the main slide valve HI, and so arranged that when the piston |915 has moved suiciently to the right for the graduating Valve IIB to uncover this port, fluid under pressure may flow through it to the vent valve piston chamber |29, whereupon the unseating of the vent valve |23 will cause an immediate sharp drop in pressure in the chamber |05, and cause the piston |99 to promptly move the mainslide valve to application position.

Upon a restoration of pressure in the brake pipe 32, and chamber |05, the piston |04 will move back to the illustrated position, where it will be noted that the cavity |3I in the main slide valve interrupts the communication between the emergency reservoir pipe 91 and the pipe 30, and where the main slide valve port I I1 connects the pipe 30 to the exhaust port |I8. Also, in release position of the piston |04, the slide Valve chamber |06 and the quick action chamber |01 are both recharged by way of port |33.

The emergency valve device I5 has been illustrated in its simplest form, but it is to be under stood that in practice I prefer to employ the corresponding type of valve device described and claimed in my copending application, Serial No. 741,063, led August 23, 1934.

The suppression selector valve device I6 is embodied in a casing containing a double beat Valve |36 urged toward an upper seated position by a spring |31, and adapted to be actuated to a lower seated position by a piston |38, in response to a supply of fluid under pressure to a chamber |39. The piston |38 is provided with a hollow stem containing a plunger |40 urged downwardly by a spring |4I. When fluid under pressure is supplied to the chamber |39, the piston |38 moves downwardly and the plunger |40 moves the stem of double beat valve |36 to shift the double beat valve to lower seated position.

When the double beat valve |36 is in the upper seated position, as illustrated, communication is established between the aforementioned pipe |30 and another pipe |42. When the double beat valve is shifted to lower seated position, this communication is cut off and the pipe connected to the atmosphere by way of an eX- haust port |43.

The cut off valve device I1 is embodied in a casing provided with a valve |45 for controlling communication between the safety control pipe 33 and a branch pipe |46 leading to the foot valve device 28. Disposed in the upper part of the valve device is a small supply controlling valve |41, urged toward seated position by a spring |48. When in seated position, the Valve |41 opens communication between a chamber |49 and the atmosphere by way of port |50. However, upon supply of fluid under pressure to a supply chamber |5| the pressure of this fluid will at a predetermined value act upon the exposed surface of the valve |41 and shift it to upper seated position, where it closes communication between the chamber |49 and the atmosphere, and opens communication between the two chambers |5| and |49. Fluid under pressure may then flow from the chamber |5| to the chamber |48, and therein act upon a diaphragm |52 to urge it downwardly to seat the valve |45, thus closing communication between the safety control pipe 33 and the branch pipe |46 leading to the foot valve.

Upon a release of fluid under pressure supplied to the chamber |5I, the valve |41 will, of course, be seated by its spring |48, and again open communication between the chamber |49 and the atmosphere, whereupon the valve |45 will unseat itself due to the resiliency of the material of which it is made.

The interlock or application insuring valve device i8 is embodied in a casing having disposed therein in spaced relationship two diaphragms |54 and |55. These two diaphragms are connected by'a yoke shaped member |56, as is clearly shown in Fig. 2. The diaphragm |54 defines with the valve device casing a chamber |51 thereabove, which chamber is in open communication with timing reservoir |58 by way of pipe |59.

The diaphragm |55 denes with the valve device casing a chamber |60 therebelow, which is in open communication with the brake cylinder pipe 59. Disposed in the chamber |68 is a spring |6|, which acts to urge the diaphragm |55 up- Wardly.

As will be observed from the arrangement shown, the area of the diaphragm |55 exposed to the chamber |60 is greater than the area of the diaphragm |54 exposed to the chamber |51. Moreover, since the spring |6| acts to assist the pressure of fluid in the chamber |60 to urge the diaphragm |55 upwardly, it follows that a low fluid pressure in the chamber |68 will balance a high fluid pressure in the chamber |51.

Attached to the follower plate connected to the diaphragm |55 is a stem |62, which acts through a member |63 and spring |64 to hold a valve |65 in seated position. The valve |65 rests, when in seated position, upon an annular seat rib |66, the area of the valve within the annular seat rib |66 being exposed to iluid pressure in the safety control pipe 33, as illustrated.

When the diaphragm |55 is moved downwardly so as to release the spring pressure holding the valve |65 upon its seat, the pressure of iluid acting upon the inner area of the valve |65 will unseat it to permit iiuid under pressure to ow from the safety control pipe 33 to the atmosphere, by way of chamber |68 between the two diaphragms |54 and |55, and port |69. The valve |65 is, however, normally held in seated position when the safety control pipe is charged, by virtue of the spring |6| acting upwardly on the diaphragm |55.

The timing reservoir |58 is in communication with the branch 29 of the control pipe 28, by way of a choke and check rvalve device |18 and a double check valve device |1I. The choke and check valve device |10, and the aforementioned choke and check valve device 18, are preferably of similar design, each comprising a choke or restricted passage |12, which provides a restricted communication both ways through the valve device, and a ball check valve device |13, which provides an unrestricted one-way communication through the valve device.

The vent valve device I8 comprises a piston |15 subject on its uppermost side to the pressure of fluid in a chamber |16, and also to the pressure of a spring |11, and on its lowermost side to the pressure of fluid in a chamber |18. Attached to the piston |15 is a vent valve |19, which is held seated when the piston |15 is in the lowermost position, as illustrated.

The chamber |16 is in open communication with the safety control pipe 33, while the chamber |18 is in open communication with a charging pipe |80 leading to the brake valve device 2|. When the brake system is charged, the pressure in the safety control pipe 33, and that in the charging pipe |80, will be substantially the same, due to the charging communication afforded by the small port |8| in piston |15. The piston |15 will, therefore, be held in its lowermost position by spring |11, as illustrated, and the small port |8| in the piston will maintain the safety control pipe pressure and the charging pipe pressure equalized. Further, for this position of the piston, the charging pipe |88 and the brake pipe 32 will be in open communication.

Upon a reduction of pressure in the safety control pipe 33, the overbalancing pressureV in the chamber |18 will shift the piston |15 upwardly and thus unseat the vent valve |19. In moving upward, the vent valve closes communication between the charging pipe |80 and the brake pipe 32, and vents the brake pipe to the atmosphere by way of port |83. The port |8| is too small to admit f rapid enough ilow from the charging pipe |80 to chamber |16 to prevent this.

It-will be'observed that disposed between the portion of the straight air pipe 3| adjacent the relay valve device and the aforementioned pipe 99 is a double check valve device |84. check valve device, as Well as the check valve devices' 21 and |1| hereinbefore referred to, are preferably of the same conventional design, and for that reason have not been illustrated in section.

Thebrake valve device 2| is preferably the same as, or similar to, that described and claimed in my copending application, Serial No. 105,659,

filed October 15, 1936. It is not essential to the understanding of the present invention that this brake valve device be either fully shown or described in detail,vand for that reason I have elected to refer only to those functions of the brake valve device essential to an understanding of the operation of the brake equipment illustrated. .Y

'I'he brake valve device' 2| is preferably operated by movement of a handle 86 in a single application zone, to control all applications of the brakes. In order to accomplish this, the brake valve is provided with a selector |81, which, in one of its two positions, conditions the brake valve for controlling the brakes by straight air operation, and which, in the other of its two positions, conditions the brake valve to control the brakes by automatic operation.

When the selector 81 is in the straight air position, and the handle 86 is in release position, the control pipe branch 29 is in communication with the atmosphere, while the brake pipe 32 is maintained charged from the feed valve pipe 34, by way of the charging pipe |80 and the vent valve device I8. When the selector |81 is in straightair position, an applicationof the brakes is eiected by moving the handle |86 to any desired position into the application Zone, whereupon communication between the control pipe branch 29 and the atmosphere is closed, and uid under pressure is supplied to this control pipe branch to a degree dependent upon the degree of movementv of the handle |86 into the application zone. During this movement of the handle |86, the brake pipe 82l continues to .be maintained charged by the brake valve device. l When the selector |81 is in the automatic position, and the handle 86 is in the release position, the control pipe branch 2,9 will be connected to the atmosphere and the brake pipe charged, as before described. When it isdesired toA effect an automatic application of the brakes, the handle |86 is rst moved to a rst service, or slackgathering, position, in the case of long trains, and then to the full service position; or, if the train is short, it may be moved to the full service position in the rst instance. In the rst service position of the handle, a small reduction in brake pipe pressure results, and in the fullservice position brake pipe pressure will continue to be reduced at a service rate until the handle is turned to the lapfposition. The degree of reduction in brak-e pipe pressure is vthus controlled according tothe time in Which the handle |86 remains in This the fullV service position. During this manipulation of the handle, the control pipe branch 29 continues to be connected to the atmosphere.

Regardless of what position the selector |81 is in, if the handle |86 is turned to the emergency position the brake pipe 32 will be' vented to the atmosphere directly, by the operation of a separate valve within the brake valve device.

The complete functioning of the brake valve device 2|, together with a full description of the complete structure, are fully covered in my above referred to copending application.

OPERATION oF THE EMBODIMENT oF FIG. l (a) Charging of the equipment At all times while the train'is running under power, or coasting; the'brake 'valve handle |86 is maintained in release position, and pressure is manually applied to a foot pedal |89 of the foot valve device 20. As before described, when the handle |86 is in release position the control pipe 28 and its branch 29 will be maintained in communication with the atmosphere, while the brake pipe 32 will be maintained charged to the desired pressure'. The safety control pipe 33 will also be maintained charged by way of the small port |8| in the piston |15 of the vent valve device I8.

The auxiliary reservoir 24 will be charged from the brake pipe by Way of the feed groove 95 in the service valve device I4, and thev emergency reservoir 25 will be charged by way of the ball check valve device 96 in the same valve device. Inv the emergency valve device I5, the quick action chamber |01 and the slide valve'chamber |06 will be maintained charged from the brake pipe by way of port |33 and passage |08. The parts will then be in the positions as illustrated.

,(b) Straight air service application Assuming now that it is desired to eiect a straight air service application of. the brakes, the selector |81 on the brake valve device is turned to the straight air position. The operator then turns the handle |86 to a position in the application zone dependent upon the desired degree of application of the brakes. Fluid under pressure will be then supplied to the control pipe 28 and its branch 29 to a degree dependent upon brake valve handle position, the double check valve 21 opening communication between the pipes 28 and 29.

Fluid under pressure in the control pipe 28 flows to the chamber 11 in the master switch device i3, and the pressure of this fluid actuates the two diaphragms 15 and 16, together with the connecting stem 14, to the left. The contact 8| rst engages stationary contact 82 and then the stationary contact 83, to successively energize the release electromagnet 1l and the application electromagnet 69, in the application and release magnet valve device l2. As a result, the release valve 61 will be seated and the supply Valve 66 will be unseated,'to supply fluid under pressure from the auxiliary reservoir 2'4 to the straight air pipe 3|, by way of pipe 13, past theunseated supply valve 66, and the passage connecting with the straight air pipe.

Fluid under pressure in the straight air pipe 3| iiows to the double check valve device |84, shifting the valve therein to its upper position, and from thence flows to the piston chamber 40, of the relay valve device I. The relay valve device l then functions, as previously described, to supply fluid under pressure from'the feed valve pipe 34 to the brake cylinder pipe 59, to a degree according to the degree of. fluid pressure established in the straight air pipe.

Fluid under pressure in the straight air pipe 3| also flows to the chamber 18 in the master switch device I3, by way of restricted passage |12 in the choke and check valve device 19, and when the pressure of this uid is substantially equal to thepressure of the fluid in the chamber 11, the two diaphragms 15 and 16 will move to the right until the contact 8| disengages from the stationary contact 93, but retains engagement with the stationary contact 82. The application electromagnet 69 will then be deenergized and spring 68 will seat the supply valve 60. As a result, the supply of fluid under pressure to the straight air pipe 3| will be lapped, and the relay valve device II will lap the supply to the brake cylinder pipe 59 leading to the brake cylinders I0. The degree of application of the brakes will then correspond to the brake valve handle position.

Fluid under pressure supplied to the branch 29 of the control pipe will also flow to the double check valve device |1I, shifting the valve therein to its upper position, and then flows to the chamber |5| in the cut-oil valve device I1, and also to the timing reservoir |58 and chamber |51 in the interlock or application insuring valve device I9, this latter flow passing through the restricted passageway |12 in the check and choke valve device |10.

In the chamber |5| of the cut-oi valve device, the pressure will increase substantially as rapidly as that in the control pipe 28, and when it has reached a predetermined value will shift the valve M1 to its upper seated position, and fluid under pressure will flow to the chamber |49, where it will actuate the diaphragm |52 downwardly to seat the valve |45. That is to say, after a predetermined degree of pressure has been established in the chamber |5I, the valve |45 will be seated and the operator may thereafter remove pressure from the foot pedal |89 of the foot valve device 20, without venting the safety control pipe 33.

The presence of the restricted passageway, or choke, |12 and the timing reservoir |58 in, or associated with, the communication to the chamber |51, in the interlock valve device, is for the purpose of causing the elapse of a predetermined interval of time before a certain critical pressure has been established in the chamber |51. When this critical pressure has been established in the chamber |51, the diaphragms |54 and |55 will be actuated downwardly, unless in the meanwhile a counterbalancing pressure has been established in the chamber |50 sufficient to hold the diaphragms inthe position illustrated.

Since the chamber |60 is connected to the brake cylinder pipe 59, it follows that the rise of pressure in this chamber will correspond to the rise of pressure in the brake cylinders I0, and if the brake cylinder pressure does not rise to a value suicient to counterbalance the pressure in chamberI51, within the time established by the presence of the choke |12 and timing reservoir |58, the diaphragms |54 and |55 will be actuated downwardly, to effect the unseating of the vent valve |65. This will, of course, result in venting the safety control pipe 33, to eiect an automatic emergency application of the brakes, as will be understood more clearly later. The interlock or application insuring valve device I9, the timing reservoir |58 and check and choke valve device |10, therefore, time and measure the degree of application of the brakesV eiected during straight air operation, and in the event that the desired degree does not materialize within a predetermined or critical interval of time, function to effect an automatic emergency application of the brakes.

During the foregoing operation, the brake pipe 32 is maintained charged, and the service valve device I4 and emergency valve device I5 do not operate, except, of course, in the event that the interlock valve device I9 operates.

To release the brakes following a straight aix' application, the brake valve handle |86 is returned to the release position, whereupon the control pipe 28-29 will be vented to the atmosphere. Diaphragms 15 andy 15 in the master switch device I3 will then move to the illustrated position, causing deenergization of both the application electromagnet B9 and release electromagnet 1|. 'I'his will result in venting the straight air pipe 3| to the atmosphere, causing the relay Valve device II to also operate to vent the brake cylinder pipe 59 and brake cylinders I0 to the atmosphere.

While specific reference has not been made at this time to the operation of the relay valve device II, it will be apparent from a consideration of the detailed description given hereinbefore, that, due to the arrangement and design of the parts illustrated, the relay valve device will function promptly and with a high degree of sensitivity in response to variations of pressure in the straight air pipe 3|.

(c) Automatic service application To effect an automatic service application of the brakes, the selector |81 on the brake valve device 2| is turned to the automatic position. Assuming now a short train, the brake valve handle |86 is turned to the full service position and left there until a suitable reduction in brake pipe pressure has been made, and thereafter turned to the lap position. The reduction in brake pipe pressure which takes place occurs at a service rate, so that only the parts of the service valve devicey I4 move to application position, the emergency valve device I5 being unresponsive to a service rate of reduction in brake pipe pressure to effect an application of the brakes, as previously described.

In the service valve device I4, however, piston 88 moves the full distance to the left, bringing the main slide valve port 98 into registration with the pipe and passage 99. Fluid under pressure will then ow from the slide valve chamber 90, and the auxiliary reservoir 24, to the pipe 99. From the pipe 99, fluid under pressure will ow to the double check valve device |84, shifting-the valve therein to its lower position, and will then flow to the relay piston chamber 40. The relay valve device will then respond as before to effect a corresponding supply of fluid under pressure to the brake cylinder pipe 59. The supply of fluid under pressure to the pipe 99 will, of course, be lapped when the degree of pressure in the pipe corresponds substantially to the degree of brake pipe reduction.

From the pipe 99, uid under pressure also flows to the connected pipe |30, which contains therein a choke |88. From the pipe |30, uid under pressure flows past the open lower seat of the double beat valve |36 in the suppression selector valve device I6, and pipe |42, to the double check valve device |1I, shifting the valve therein t0 the lower position, and then flowing to the chamber in the cut-off valve device- IT, and to the timing reservoir |58 and chamber |51 of the interlock valve device I9.

It will thus be seen that, during an automatic service application of the brakes, fluid under pressure is supplied to the cut-off valve chamber |5i and interlock valve chamber |51, just as it was during a straight air service application of the brakes.

The interlock or application insuring valve device |9, therefore, times and checks the degree of application of the brakes effected by operation of the service valve device Ill, and if sufiicient brake cylinder pressure is established durf ing the interval of time while the pressure in the chamber |57 is rising to a critical or predetermined degree, then the parts of the interlock valve device remain in the position illustrated; but if the desired brake cylinder pressure should not materialize, then the parts of the interlock valve device function to vent the safety control pipe 33 to effect an emergency application.

To eifect a rele-ase of the brakes following an automatic service application, the brake valve handle |89 is again returned to release position, whereupon the brake pipe 32 will be recharged from the feed valve pipe 39. Recharging of the brake pipe causes the parts of the service valve device |65 to assume the release position as illustratcd, whereupon the pipe 99 will be vented to the atmosphere by way of cavity |99 in the main slide valve 955, and exhaust port IUI. This will, of course, result in the relay valve device releasing fluid under pressure from the brake cylinders i9.

(d) Emergency application An emergency application of the brakes may result from either of three operations. The first of these, and the one which is most concerned with the present invention, is by operation of the interlock or application insuring valve device I9; the second is by operation of the brake valve handle |86 to emergency position; and the third by release of pressure manually applied to the foot pedal |99 of the foot valve device 29, i. e., a safety control emergency application.

Considering now theI operation of the interlock or application insuring valve device i9, as has been previously described if the pressure of fluid supplied to the chamber |51 should rise to a predetermined or critical value before sufiicient brake cylinder pressure has been established in the chamber |99 to prevent downward movement of the two diaphragms |54 and |55, then the resulting downward movement of these two diaphragms will effect the unseating of the vent valve |95. This will. of course, rapidly vent the safety control pipe and as a result the overbalancing pressure in the chamber |7118 of the vent valve device i8 will shift the Vpiston |15 therein upwardly, first closing communication between the brake pipe 32 and the charging pipe |89, and then venting the brake pipe to the atmosphere by way of the large exhaust portr |89.

The reduction in brake pipe pressure which takes place is at an emergency rate, so that the emergency valve device l5, as well as the service valve device Ul, respond. The piston |99 in the emergency valve device i5 will move to its extreme right hand position. at the same time causing unseating of the vent valve |23 to further reduce brake pipe pressure, and also connecting the emergency reservoir 25 to the pipe 3|), thus supplying uid under pressure to the pipe 30 while blanking communication to the pipe 99. The supply to the pipe 39 is by way of pipe 9'?, cavity I3| in the main slide valve |I|, and the passage connecting with pipe 30. Since the pipe 39 is a branch of the control pipe 28, it will be obvious that the supply of fluid under pressure to the control pipe will effect the operation of the master switch device i3, to cause the application and release magnet valve device |2 to supply iiuid under pressure to the straight air pipe 3l.

Since the service valve device I4 effects a supply of uid'under pressure to the pipe 99, it will be apparent that the double check valve device |84 will select between the pressure of fluid in the pipe 99 and that in the straight air pipe 3|. The service port 98 in the service valve device M is a relatively small port, so that the build up of ressure in the pipe 99 takes place at a slower rate than the build up of pressure in the straight air pipe 9|, and as a consequence, the double check valve device will open communication between the straight air pipe 3| and the relay piston chamber 49.

Further, the emergency reservoir 25 is preferably made larger than the auxiliary reservoir 2A, so that it will deliver :duid at a higher ultimate pressure.

In the event, however, that the application and release magnet valve device i2 should fail to function, the double check valve device |94 will open communication between the pipe 99 and the relay piston chamber Mi. In any event, the relay valve device iI will respond to the pressure of fluid supplied to the chamber 49 to effect an application of the brakes, The volume of the emergency reservoir 25 is further made sufcient so that, when the pressure established in the control pipe 28 is due to flovv from it, the pressure Will be a maximum, thereby causing a maximum degree of application of the brakes.

Fluid under pressure supplied to the branch control pipe 39 ilowsrto the chamber |39 in the suppression selector valve device I6, and the pressure of iiuid in this chamber shifts the piston |38 downwardly and thereby actuates the double beat valve |39 to lower seated position. This places the pipe |42 in communication with the exhaust port |43, so that fluid under pressure cannot be supplied to the cut-'01T valve chamber |5| and the interlock valve chamber |57! as a result of supply of fluid under pressure to the pipe 99. The reason for interrupting communication between the pipes |39 and |42 will be clear later.

From the foregoing, it will be clear that, upon failure 'of a service application of the brakes tomaterialize to a predetermined degree in a chosen length of time, the interlock or application insuring valve device I9 will function to effect an emergency application of the brakes, so that the train will be stopped promptly and without delay. .l

. Considering now initiating an emergency application of the brakes by turning the brake valve handle |86 to an emergency position, this unseats a special valve responsive only to movement of the handle to emergency position, to vent the brake pipe 32 at an emergency rate. This, of course, results in an emergency application effected in substantially the same manner as just described for the first type of emergency application.

When the brake valve handle |86 is moved to emergency position at a time when the selector |97 is in the straight air position, fluid under pressure Will be supplied to Ythe control pipe branch 29, but the pressure of this supply will be lower than that supplied to the branch 30 by the emergency valve device l5, soi that the double check valve device 27 will open communication between the branch 39 and the main control pipe 2S.

To release the brakes following this type of emergency application, the brake valve handle |86 is returned to release position, where the brake pipe is recharged, and the parts in the service valve device I4 and emergency valve device l5 are as a result returned to the illustrated position, to effect the release.

Considering now the third method of effecting an emergency application; that is, by release of pressure manually applied to the foot pedal |89, this results in venting the safety control pipe 33, whereupon the vent valve device |8 functions to vent the brake pipe to the atmosphere at an emergency rate. It will be seen that each of the methods for effecting an emergency application results in venting the brake pipe to the atmosphere at an emergency rate, so that the resulting operation of parts is substantially the same. In each of the types of emergency applications described, the suppression selector valve device I6 closes communication between the pipe |42 and the pipe |39, but this is of significance only with respect to the last mentioned, or safety control, emergency application. If fluid under pressure is supplied to the cutoff valve chamber while the foot valve 210 is venting the safety control pipe, the valve |95 will be seated and permit the safety control pipe to be recharged by way of port |8| in the vent valve piston |15, thus possibly causing an undesired release of the brakes. By interrupting the communication between pipes |30 and |42 this is prevented.

EMBODIMENT oF FIG. 3

The embodiment of Fig. 3 is intended to show only so much of the brake system illustrated in Fig. l as is necessary toindicate the extent of the modifications made. These modifications comprise the employment of a combination vent and suppression valve device |99, substituted for both the vent valve device I8 and the suppression selector valve device l5 of Fig. l, and also the employment of a different type interlock or application insuring valve device |9| for the corresponding interlock valve device I9 of Fig. 1.

'Ihe vent Valve portion of the combination vent and suppression valve device |99 comprises essentially the parts of the aforedescribed Vent i valve device I8, which parts are indicated by like numerals, while the suppression valve portion comprises a supply valve |92 and a release valve |93 connected together by a stem |94. Two springs |95 and |96 urge the supply valve |92 toward seated position and the release valve |93 toward unseated position.

A diaphragm |97, having one side thereof eX- posed to a chamber |98 connected to the safety control pipe 33 by way of passage |99, functions when the safety control pipe is charged to maintain the release valve |93 seated and the supply valve |92 unseated. For this position of the two valves, the aforementioned pipe |30 is connected to the aforementioned pipe |42. When the safety control pipe pressure decreases below a predetermined value, the two springs |95 and |96 function to seat the supply valve |92, to close communication between the two pipes |39 and |42, and to unseat the release valve |93, to vent the pipe |42 to the atmosphere by way of exhaust port 200.

The interlock valve device |9| comprises two diaphragms 202 and 203 connected by a stem 204, the latter diaphragm being larger than the former and the stem being recessed to receive and move coextensive with movement thereof a slide valve 2|05.

A spring 206 acts upon the lower diaphragm 20'3 toy position the parts as illustrated, whereupon the diaphragm 202 is held in contact with stops 201. For this position of the slide valve 205, feed valve pipe 34 is connected by cavity 203 in the slide valve to a passage 209, which passage leads to a timing reservoir 2|0 and to a chamber 2|| to one side of a diaphragm valve 2|2. The diaphragm valve 2|2 is adapted to engage an annular seat rib 2|3, to close communication between a chamber 2M, which is in communication with an atmospheric port 2|6 by way of passage 2H, and a passage 2|8 connecting with the safety control pipe 33.

Chamber 220 above the smaller diaphragm 202 is connected by pipe and passage 2|9 to the control pipe 28, while chamber 22| below the larger diaphragm 293 is connected to the brake cylinder pipe 59.

In the operation of the brake equipment, with the brake valve handle |86 in release position, and the brake pipe 32 fully charged, the parts of the two valve devices |90' and |9| will be in the positions as illustrated. In the interlock or application insuring valve` device |9|, it will be noted that the timing reservoir 2|0 is charged from the feed valve pipe 34.

When now a straight air application of the brakes is effected, fluid under pressure supplied to the control pipe 28 will ow to chamber 220 and when the pressure in this chamber has reached a certain degree, the diaphragms 202 and 203 will be actuated downwardly against opposition of spring 206. 'I'he cavity 208 in the slide Valve 205 will then disconnect the passage 209 from the feed valve pipe 34 and connect passage 209 to the atmospheric passage 2|6. This will, of course', vent the timing reservoir 2||0 and the chamber 2|| to the atmosphere.

However, this venting will take place at a slow rate due to the presence of the restriction 222 in the passage 2 6 at the seat of the slide valve 205. If the slide valve 205 is permitted to remain in this lower position until the pressure of the timing reservoir 2|0 and the chamber 2|| is permitted to fall below a predetermined value, then the pressure acting below the diaphragm valve 2|2, due to the connection with the safety control pipe 33, will unseat the diaphragm valve and vent the safety control pipe to the atmosphere, by way of chamber 2|4, passage 2|? and atmospheric port 2|6. Safety control pipe pressure will be reduced at an emergency rate, so that the vent valve |79 of the vent and suppression valve device |90 will be operated to vent the brake pipe to the atmosphere at an emergency rate, to thus effect an emergency application of the brakes.

However, if the brake cylinder pressure materializes to the desired degree before the pressure in the timing reservoir 2|!! has been reduced below the said predetermined value, then` brake cylinder pressure acting on the larger diaphragm 203, together with the pressure of the spring 205, will shift the slide valve 205 to its upper position, thus terminating the venting of the timing reservoir 2|0, and again connecting it to the feed valve pipe 34. It will thus be seen that the interlock or application insuring valve device |9| while of diierent construction and operating in somewhat different manner from the like valve device |9 of Fig. 1, performs substantially the same function.

Considering now the vent and suppression valve device |96, it will be observed that the parts of this valve device will remain in the position illustrated until the safety control pipe 33 is Vented to the atmosphere, or the pressure therein substantially reduced. When the pressure in the safety control pipe 33 is reduced, thel piston |15 will ,move upwardly to vent the brake pipeto the atmosphere, while the two springs |95 and |96 will shift the supply Valve |92 to seated position and release valve |93 to unseated position. The effect of shifting the supply valve |32 to seated position and the release valve |93 to unseated position is to prevent during a safety control emergency application any tendency of the emergency application. to release itself, as described in connection with the embodiment of Fig. 1.

It will be apparent from a consideration of the description of the embodiment of Fig. 3 thus given, that the new valve devices provided may be used with the complete brake system of Fig. 1 without impairing any of the functions of that system.

EMBODIMENT oF FIG. 4

The embodiment of Fig. 4 illustrates an arrangement whereby an interlock or application insuring valve device 224, together with a magnet valve device 225 and a switch device 226, are substituted for the previously considered interlock or application insuring valve devices. The other parts of this embodiment correspond to the parts shown in the embodiment of Fig. 3, and are similarly connected in the brake system of Fig, 1. The interlock valve device 224 comprises a piston 221 operable upon supply of fluid under pressure to a chamber 228 to move downwardly to shift a double beat valve 229 from upper seated position to lower seated position, against the bias of spring 230. The piston 221 is provided with a hollow stem 23| having disposed therein a plunger 232 urged downwardly by a spring 233, the plunger 232 engaging the fluted stem of the double beat Valve 229 to shiftA it from upper seated position to lower seated position.

When fluid under pressure is released from the chamber 228, spring 230 moves the piston 221 upwardly and at the same time shifts the double beat valve 229 from lower seated position to upper seated position. Fluid under pressure is supplied to the chamber 228 from the control pipe 28 by way of a valve 236, which is urged toward a lower seated position by a spring 231. The valve 236 is normally maintained seated on an annular seat rib 238, and the area of the valve Within the seat is exposed to the pressure of fluid in the pipe 28. When this pressure exceeds a predetermined value, the valve 236 will be actuated to upper seated position, closing communication between the chamber 228 and exhaust port 239, anld.

opening communication between the chamber 228 and the pipe 28.

- The chamber 24|) below the piston 221 is in open communication with the atmosphere by way of'passage 24|, so that, when the piston is actuated downwardly due to fluid pressure in the chamber 228, it will be held in its lowermost position.

When the double vbeat valve 229 is in upper seated position, communication is established between the feed valve pipe 34 and pipe 242 leading to timing Vreservoir 235 and to double check valve device 243. When the double beat valve 229 is in lower seated position, this communication is cut off and the pipe 242 is connected to an atmospheric port containing a restriction 244.

The double check valve device 243 is of conventional design, and whereas one inlet communication is connected to the pipe 242 the other inlet communication is connected tothe brake cylinder pipe 55. The outlet communication is connected to pipe 245 leading to a chamber 246 of the switch device 226.

kThe switch device 226 is embodied in a casing containing a piston 241 subject on its lowermost side to the pressure of fluid in the chamber 246, and on its uppermost side to the pressure of a spring 248. When the piston 241 is in. the uppermost position, a bridging contact 249, carried byand insulated from the piston stem, disengages from two stationary contacts 250. When the piston is in its lowermost position, the contact 249 engages and bridges the two contacts 259.'

The contacts 249 and 250 control the energization of an electromagnet 25| in the magnet valve device 225, current being supplied from a battery 252.

The magnet valve device 225 contains a supply valve 254 urged toward a seated position by a spring 255, and toward an unseated position by the electromagnet 25| when energized. When the Valve 254 is unseated, communication. is established between the safety control pipe 33 and an exhaust port 256, and when the valve 254 is seated this communication is cut off.

In operation of the brake system comprising the apparatus of Fig. 4, iiuid under pressure supplied to the control pipe 23 flows to the seat of the valve 236, and when the value of this prese sure reaches the aforesaid predetermined unseating value, the valve unseats and permits fluid under pressure to fiow to the piston chamber 228. The piston 221 is thereupon actuated downwardly to shift the double beat valve 229 from upper seated position tol lower seated position. It will be observed that, in the upper seated position of the double beat valve 229, timing reservoir 235 is charged from the feed Valve pipe 34. Therefore, when the double beat valve shifts to lower seated position, the timing reservoir 235 is connected to the atmospheric port containing the restriction 244.

So long as the timing reservoir 258 is charged above a predetermined degree, the switch device 226 will maintain the contact 249 disengaged from the contacts 259. When, however, the pressure in the timing reservoir, and consequently that in the chamber 243 of the switch device 26, diminishes below the said predetermined closing value, the contact 249 will engage the contacts 256, to energize the electromagnet 25|. This will unseat the valve 254 and vent the safety control pipe 33 to the atmosphere, resulting in an emergency application of the brakes as before' described.

If, however, before the pressure in the timing reservoir 235 and chamber 246 has diminished below the aforesaid predetermined closing value, the pressure in the brake cylinders l0 should reach a value exceeding timing reservoir pressure, the valve in the double check Valve 243 Willshift to the left and open communication between the brake cylinder pipe 59 and the pipe 245. Brake cylinder pressure will thereafter be effective in maintaining the switch contact 249 disengaged from the contacts 256, thereby preventing an emergency application.

It will thus been seen that an emergency application will be effected upon a failure of brake cylinder pressure to be developed to a predetermined degree within a chosen length of time, following initiation of a service application of the brakes.

MoDIFIcATIoN or FIG. 5

The embodiment shown in this figure differs from the previous embodiments essentially in the employment of a different type of interlock Valve device, designated at 266, and a different type of vent valve device, indicated at 26|.

The interlock or application insuring valve -device 260 is embodied in a casing containing a piston 262, subject on one side to pressure of fluid in a chamber 263, and also to the pressure of a spring 266, and subject on the other side to the pressure of fluid in a chamber 265. The chamber 263 is connected to the brake cylinder pipe 59, while the chamber 265 is connected by way of pipe 266 to a timing reservoir 261, and by way of a check and choke valve device 268 (which is of the same design as those heretofore described), to the control pipe 28, so that fluid under pressure supplied to the control pipe will flow to both the timing reservoir 261 and the chamber 265.

The piston 262 is provided with a stem 269,

351 which is recessed to receive and move coextensive therewith a slide valve 216. The slide valve is held upon its seat by a pin 21| urged downwardly by a spring 212.

When the piston 262 is in the position illustrated, a cavity 213 in the slide valve connects a pipe and passage 215 to an exhaust port 216. When the piston 262 is moved to the left, this communication is cut off and pipe and passage 215 is opened to the chamber 265.

The vent valve device 26| contains a piston 211-which is operated upon supply of fluid under pressure to the pipe 215 to unseat a vent valve 218 against the bias of a spring 219. Unseating of the vent valve 216 opens a communication between the brake pipe 32 and the atmosphere, by

Way of port 280, to vent the brake pipe toy the atmosphere at .an emergency rate.

In the operation of the apparatus illustrated in Fig. 5, when fluid under pressure is supplied to the control pipe 28, it flows by way of the restriction |12 in the valve 268 to the timing reservoir 261 and to the chamber 265. It will be observed that the piston 262 seats upon a seat rib 28| when in its right hand position, so that the area of the piston exposed to the chamber 265 is less than the area exposed to the chamber 263. Due to the presence of the choke |12 and timing reservoir 261, a predetermined interval of time will elapse before sufficient pressure is built up in the chamber 265, and timing reservoir 261, to` shift the piston from its seat 28|, but when it once disengages from the seat it will move promptly to the left, due to the increased area exposed to the pressure in chamber 265.

If, however, before the piston 262 disengages from seatI 28|, brake cylinder pressure has built up sufficiently, the piston 262 will be held in its right hand position although the pressure in chamber 265 reaches its maximum value, because the area of the piston exposed to brake cylinder frentes pressure is greater than that exposed to the pressure in chamber 265. On the other hand, if sufficient brake cylinder pressure fails to materialize within said predetermined length of time, the overbalancing pressure from the chamber 265 will shift the piston 262 to its left hand position, and fluid under pressure will be supplied to the vent valve device to effect unseating of the valve 218. This will, as before described, vent the brake pipe to the atmosphere at an emergency rate to effect an emergency application of the brakes.

In all of the foregoing embodiments oi' my invention, it will be observed that, in one form or another, fluid under pressure supplied to the control pipe is balanced against brake cylinder pressure in determining the operation of the application insuring means. If the brake cylinder pressure materializes to the proper degree, in the desired time, the active parts of the insuring means are maintained in a biased or balanced position, but in the event that the brake cylinder pressure fails to materialize properly the balance is not maintained and an emergency application results.

While I have described several embodiments of my invention, and have illustrated each by a specic construction, it is not my intention to be limited to the particular devices or arrangements shown, nor otherwise than by the spirit and scope of the appended claims,

Having noW described my invention, what I claim as new and desire to secure by Letters Patent, is:

1. In a vehicle brake system, in combination, a brake equipment comprising a control pipe to which iiuid under pressure is supplied to effect a straight air application of the brakes and also comprising a normally charged pipe in which the pressure of fluid is varied to effect an automatic application of the brakes, means responsive to control pipe pressure for effecting after a predetermined delayed interval of time a variation of pressure in said charged pipe, and means responsive to the degree of application of the brakes and operable to prevent said variation in charged pipe pressure when the degree of application attains a given value before the elapse of said predetermined interval of time.

2. In a vehicle brake system, in combination, a control pipe to which fluid under pressure is supplied to effect a straight air application of the brakes, a normally charged pipe in which the pressure of fluid is decreased to effect an automatic application of the brakes, means responsive to a supply of uid under pressure to said control pipe for effecting after a predetermined delayed interval of time a reduction of pressure in said charged pipe, and means responsive to the actual degree of application of the brakes for inhibiting the operation of said last means when the degree of application attains a chosen value before the elapse of said predetermined interval of time.

3. In a vehicle brake system, in combination, a brake cylinder, a control pipe, a brake pipe, means responsive to the supply of fluid under lpressure to said control pipe to eifect a supply of fluid under pressure to said brake cylinder corresponding to the degree of pressure established in said control pipe, means responsive to a reduction of pressure in said brake pipe for effecting a supply of fluid under press-ure to said brake cylinder to a degree corresponding to the degree of reduction in brake pipe pressure, means responsive to control pipe pressure for effecting u a brake cylinder, a control pipe to which iiuidA after a predetermined delayed interval of time a reduction of pressure in said brake pipe, andl means responsive to fluid at brake cylinder pressure for inhibiting the operation of said last means when brake cylinder pressure attains within said predetermined interval of time a value corresponding substantially to control pipe pressure.

4. In a vehicle brake system, in combination, a brake cylinder, a control pipe to which fluid under pressure is supp-lied to effect a supply of fluid under pressure to said brake cylinder, a brake pipe in which the pressure of fluid is reduced to also eect a supply of fluid under pressure to said brake cylinder, and means including a valve device subject to both fluid at control pipe pressure and fluid at brake cylinder pres'- sure, and operable in the event that brake' cylinder pressure fails to materializeto a chosen degree within a predetermined length of time, following supply of fluid under pressure to said y control pipe, to effect a reduction of pressure in said brake pipe.

5. In a vehicle brake system, in combination, a

, brake cylinder, a control pipe to which uid under pressure is supplied to effect a supply of fluid under pressure to said brake cylinder by straight air operation, a normally charged pipe in which the pressure of iiuid is reduced to effect a supply of fluid under pressure to said brake cylinder by automatic operation, a valve device subject both to control pipe pressure and to brake cylinder pressure, and means associated with said valve device for causing it to operate after a predetermined length of time, following supply of fluid under pressure to said control pipe, to effect a reduction of pressure in said normally charged pipe in the event that brake cylinder pressure fails to attain a chosen value within a predetermined length of time, c

6. In a vehicle brake system, in combination, a brake cylinder, a control pipe to which fluid under pressure is suppliedto effect a straight air application of the brakes, means responsive to the supply of fluid under pressure to said control pipe to effect a supply of fluid under pressure to said brake cylinder, a normally charged pipe, means responsive to the reduction of pressure in said normally charged pipe for also effecting a supply of fluid under pressure to said brake cylinder, and valve means subject to both control pipe pressure and brake cylinder pressure and operative upon a predetermined differential between control pipe pressure and brake cylinder pressure to effect a reduction of pressure in said normally charged pipe.

'7. In a vehicle brake system, in combination, a brake cylinder, a control pipe, a brake pipe, electropneumatic means responsive to control pipe pressure for effecting a supply of fluid under pressure to said brake cylinder to a degree corresponding to the pressure established in said control pipe, means responsive to reduction of pressure in said brake pipe for effecting a supply of fluid under pressure to said brake cylinder corresponding to the degree of reduction in brake pipe pressure, a valve device subject to both control pipe pressure and brake cylinder pressure and operative when control pipe pressure is greater than brake cylinder pressure by a predetermined differential to effect a reduction ofkpressure in said brake pipe, and means for delaying the response of said valve device to control pipe pressure.

8. In a vehicle brake system, vin combination,

under pressure is supplied to effect a straight air application of the brakes, a normally charged pipe in which the pressure of iiuid is reduced to effect an automatic application of the brakes, a valve device having a movable means subjectk on' one side to fluid at control pipe pressure and on the other side to fluid at brakecylinder pressure, and operable when control pipe pressure exceeds brake cylinder pressure by a predetermined differential to open a communication between said normally charged pipe and the atmosphere, and means for delaying the response of said mov-i able means to the establishment of control pipe pressure. 1

9. In a vehicle brake system, in combination, a brake cylinder, a control pipe to which vfluid under pressure is supplied to effect a supply of fluid under pressure to said brake cylinder lby straight air operation, a normally charged pipe in which the pressure of fluid is reduced to effect a. supp-ly of fluid under pressure to saidv brake cylinder by automatic operation, a valve device comprising a first movable abutment subject to control pipe pressure and a second movable abutment subject to brake cylinder pressure,

said valve device also having a valve shiftable to establish communication between said normally charged pipe and the atmosphere, andalso having means interconnecting said two movable abutments and operable when control pipe pressure exceeds brake cylinder pressure by a predetermined ldifferential to cause shifting of said valve, and a choke device and timing reservoir for delaying the response of said first movable abutment to control pipe pressure.

10. In a vehicle brake system, in combination, a brake cylinder, a control pipe to which fluid under pressure is supplied to effect a supply of fluid under pressure to said brake cylinder by straight air operation, a normally charged'brake pipe in Which the pressure of fluid is reduced to effect a supply of fluid under pressure to said brake cylinder by automatic operation, an automatic valve device operable upon an emergency rate of reduction in brake pipe pressure toA effect a supply of fluid under pressure to said brake cylinder, and means including a valve device subject to both control pipe pressure and brake cylinder pressure and operable upon the failure of brake cylinder pressure to materialize to a predetermined degree within a chosen length of time, following supply of iiuid under pressure to said control pipe, to effect an emergency rate of reduction in brake pipe pressure to effect an emergency application of the brakes.

11. In a vehicle brake system, in combination', a brake cylinder, a control pipe to which fluid under pressure is supplied to effect a supply4 of fluid under pressure to said brake cylinder by straight air operation, a brake pipe in which the pressure of fluid is reduced to effect asupply duced below a predetermined value to effect a reduction of pressure in said brake pipe.

A12. In a vehicle brake system, in combination, a .brake cylinder, a control pipe to whichv fluid under pressure is supplied to effect a supply of fluid under pressure to said brake cylinder by straight-air operation, a brake pipe in which the pressure of fluid is reduced to effect a supply of fluid under pressure to said brake cylinder by automatic operation, valve means subject to bothv control pipe pressure and brake cylinder pressure and operable in a normally biased position to connect said timing reservoir to a source of'supply of fluid under pressure, and operable in response to control pipe pressure to connect said timing reservoir to the atmosphere. through a restricted communication, and a ventY valve device operable when timing reservoir pressure has reduced below a predetermined value to effect a reduction of pressure in said brake pipe, said valve means being operable in response to a rise of brake cylinder pressure in a given length of time to disconnect said timing reservoir from the atmosphere and to reconnect said timing reservoir to said source of supply to prevent the reduction of pressure in said brake pipe.

13. In a vehicle brake system, in combination, a brake cylinder, means for effecting a supply of fluid under pressure to said brake cylinder byj straight air operation, means including a switch device having a chamber normally charged with fluid under pressure and operative upon a reduction of pressure in said chamber below a predetermined value to effect a supply of fluid under pressure to said brake cylinder by automatic operation, means operative during straight air operation to effect said predetermined reduction of pressure in said chamber in a chosen length of time, and means operative also during straight air operation to maintain the pressure insaid chamber above said predetermined value in-the event that brake cylinder pressure attains said predetermined value before the elapse of said chosen time.

`:14. In a vehicle brake system, in combination, a brake cylinder, means for supplying fluid under pressure to said brake cylinder by straight air operation, Imeans including a switch device having a chamber normally charged with iuid under pressure and operative upon a predetermined reduction of pressure in said chamber to effect a supply of fluid under pressure to said brake cylinder by automatic operation, means operative to reduce the pressure in said chamber when effecting a straight air application of the brakes, and means operative to maintain the pressure in said chamber substantially at brake cylinder pressure during straight air applications of the brakes.

15. In a vehicle brake system, in combination, a brake cylinder, a control pipe, means for eiecting a supply of fluid under pressure to said control pipe to effect an application of the brakes, means responsive to the pressure of fluid supplied to said control pipe for effecting a supply of fluid under pressure to said brake cylinder, a reservoir normally charged vwith fluid under pressure, a switch device having a chamber subject to the pressure of fluid in said reservoir and operable upon a decrease of pressure in said chamber below a predetermined value for effecting a supply of uid under pressure to said brake cylinder by automatic operation, means responsive to the pressure of uid supplied to said control pipe for slowly reducing the pressure of fluid in said reservoir and in said switch chamber, said means being so constructed and arranged as to require a denite interval of time in which to reduce the pressure in said switch chamber to said predetermined value, and means operative in the event that brake cylinder pressure attains a value equal to or greater than said predetermined value within said definite intervalof time to maintain the pressure in said switch chamber abovesaid predetermined value to prevent the supply of fluid under pressure to the brake cylinder by said automatic operation.

16. In a vehicle brake system, in combination, a brake cylinder, a control pipe to which uid under pressure is supplied to effect a supply of fluid under pressure to said brake cylinder by straight air operation, a brake pipe in which the pressure of -fiuid is reduced to effect a supply of fluid under pressure to said brake cylinder by automatic operation, a valve device having a movable abutment subject on one side to pressure of iiuid in said control pipe and on the other side to fluid at brake cylinder pressure, said valve device being vnormally biased to a given position and being operable when control pipe pressure exceeds brake cylinder pressure by a predetermined differential to be actuated to an operative position, means responsive to movement of said valve device to said operative position for effecting a reduction of pressure in said brake pipe, and means for delaying the response of said movable abutment to control pipe pressure.

1'7.v In a vehicle brake system, in combination, a brake cylinder, a control pipe to which fluid under pressure is supplied to effect a supply of uid under pressure to said brake cylinder by straight air operation, a brake pipe in which the pressure of fluid is reduced to effect a supply of fluid under pressure to said brake cylinder by automatic operation, an interlock valve device having a piston subject on one side to control pipe pressure and on the other side to brake cylinder pressure, a vent valve device operable upon a supply of fluid under pressure thereto to effect a reduction in brake pipe pressure, said interlock valve device being operative when control pipe pressure exceeds brake cylinder pressure by a predetermined differential to effect a supply of fluid under pressure to said vent valve device, and timing means for delaying the response to said interlock valve device to control pipe pressure.

18. In a vehicle brake system, in combination, a brake equipment comprising a normally discharged pipe to which fluid under pressure is supplied when elfecting a service application of the brakes and also comprising a normally charged pipe in which the pressure of fluid is varied to effect an automatic application of the brakes, means responsive to the pressure supplied to said normally discharged pipe for effecting after a predetermined delayed interval of time a variation of pressure in said charged pipe, and means responsive to the degree of a service application of the brakes and operative to prevent said variation in `charged pipe pressure when the degree of a service application attains the desired value before the elapse of vsaid predetermined interval of time.

19. In a vehicle brake system, in combinationl a normally charged pipe in which the pressure of fluid is decreased to effect an automatic application of the brakes, means for establishing a regulatory fluid pressure to effect an application of the brakes by other than operation of said automatic means, means responsive to said regulatory pressure for effecting after a predetermined delayed interval of time a reduction of pressure in said charged pipe, and means responsive to the actual degree of application of the brakes caused by said regulatory pressure for inhibiting the operation of said last named means When the degree of application attains a chosen value before the elapse of said predetermined interval of time.

20. In a vehicle brake system, in combination, a brake cylinder, means for establishing a control pressure to eiect a supply of fluid under pressure to said brake cylinder, a brake pipe in which the pressure of uid is reduced to also effect a supply of fluid under pressure to said brake cylinder, and means including a valve device subject to both said control pressure and uid at brake cylinder pressure, and operable in the event that brake cylinder pressure fails to materialize to a chosen degree within a predetermined length of time, following the establishment of said control pressure, to effect a reduction of pressure in said normally charged pipe.

21. In a vehicle brake system, in combination, a service automatic valve device operable to establish a control pressure to eiect a service application of the brakes, means including a normally charged pipe operable upon an emergency reduction of pressure in said pipe to effect an emergency application of the brakes, and means including a valve device governed both by the degree of said control pressure and the actual degree of application of the brakes for effecting operation of said emergency means in the event that the actual degree of application of the brakes fails to materialize to a chosen degree within a predetermined interval of time following the establishment of said control pressure by said service automatic valve device.

ELLIS E. HEWITT. 

